Geoelectric hazard maps for the continental United States

Love, Jeffrey J.; Pulkkinen, A.; Bedrosian, Paul A.; Jonas, Seth; Kelbert, Anna; Rigler, E. J.; Finn, C.; Balch, C. C.; Rutledge, Robert W.; Waggel, Richard M.; Sabata, Andrew T.; Kozyra, J. U.; Black, Carrie

doi:10.1002/2016gl070469

Cited by 42 publications

(40 citation statements)

References 49 publications

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“…In Figure c, we compare our hazard estimates with those obtained previously for the continental United States (Love & Bedrosian, ; Love et al, ). Whereas, we calculate the 1‐min E h analyzed here by convolving geomagnetic time series with magnetotelluric impedances, the hazard maps for the continental United States were indirectly derived: a statistical analysis was performed of historical global geomagnetic variation in terms of the amplitudes of waveforms having specific periods and polarizations and persisting for a given duration of time; the waveforms were convolved with magnetotelluric impedances from various survey sites.…”

Section: Geoelectric Hazard Mapsmentioning

confidence: 77%

Geoelectric Hazard Maps for the Pacific Northwest

et al. 2018

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Maps of extreme value, horizontal component geoelectric field amplitude are constructed for the Pacific Northwest United States (and parts of neighboring Canada). Multidecade long geoelectric field time series are calculated by convolving Earth surface impedance tensors from 71 discrete magnetotelluric survey sites across the region with historical 1-min (2-min Nyquist) geomagnetic variation time series obtained from two nearby observatories. After fitting statistical models to 1-min geoelectric amplitudes realized during magnetic storms, extrapolations are made to estimate threshold amplitudes that are only exceeded, on average, once per century. One hundred-year geoelectric exceedance amplitudes range from 0.06 V/km at a survey site in western Washington State to 9.47 V/km at a site in southeast British Columbia; 100-year geoelectric exceedance amplitudes equal 7.10 V/km at a site north of Seattle and 2.28 V/km at a site north of Portland. Systematic and random errors are estimated to be less than 20%, much less than site-to-site differences in geoelectric amplitude that arise from site-to-site differences in surface impedance. Maps of 100-year exceedance amplitudes are compared with the peak geoelectric amplitudes realized during the March 1989 magnetic superstorm; it is noted that some storms of relatively modest intensity can generate localized geoelectric fields of relatively high amplitude. The geography of geoelectric hazard across the Pacific Northwest is closely related to known geologic and tectonic structures.

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Section: Geoelectric Hazard Mapsmentioning

confidence: 77%

Geoelectric Hazard Maps for the Pacific Northwest

et al. 2018

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“…These include Bedrosian and Love (2015), who use 3-dimensional magnetotelluric EarthScope impedances to estimate the geoelectric response of a simulated time-varying geomagnetic field across northern North America. Love et al (2016a) used these impedances to produce a hazard map of half of the USA by convolving these impedances against latitudedependent maps of extreme geomagnetic activity. Torta et al (2017) improved the estimate of the phase and magnitude of measured geomagnetically induced currents (GICs) in power transmission systems by modeling local 2-and 3-dimensional conductivity structures with their impedances.…”

Section: Introductionmentioning

confidence: 99%

Geoelectric hazard assessment: the differences of geoelectric responses during magnetic storms within common physiographic zones

Cuttler

Love

Swidinsky

2018

Earth Planets Space

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Geomagnetic field data obtained through the INTERMAGNET program are convolved with with magnetotelluric surface impedance from four EarthScope USArray sites to estimate the geoelectric variations throughout the duration of a magnetic storm. A duration of time from June 22, 2016, to June 25, 2016, is considered which encompasses a magnetic storm of moderate size recorded at the Brandon, Manitoba and Fredericksburg, Virginia magnetic observatories over 3 days. Two impedance sites were chosen in each case which represent different responses while being within close geographic proximity and within the same physiographic zone. This study produces estimated time series of the geoelectric field throughout the duration of a magnetic storm, providing an understanding of how the geoelectric field differs across small geographic distances within the same physiographic zone. This study shows that the geoelectric response of two sites within 200 km of one another can differ by up to two orders of magnitude (4484 mV/km at one site and 41 mV/km at another site 125 km away). This study demonstrates that the application of uniform 1-dimensional conductivity models of the subsurface to wide geographic regions is insufficient to predict the geoelectric hazard at a given site. This necessitates that an evaluation of the 3-dimensional conductivity distribution at a given location is necessary to produce a reliable estimation of how the geoelectric field evolves over the course of a magnetic storm.© The Author(s) 2018. This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

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“…This is not the case for a 1‐D conducting Earth. Furthermore, ground electric fields resulting from a GMD of a given magnitude and source magnetic field orientation can be intensified substantially (by up to an order of magnitude) for the 3‐D case relative to the 1‐D case [ Thomson et al ., ; Bedrosian and Love , ; Love et al , ] and can vary dramatically in direction and intensity from one GMD to another since the time‐frequency content of source field intensity and orientation is unique to each GMD. An important consequence of this is that no general linear scaling exists between the ground electric fields predicted from a GMD acting on a 1‐D conductivity model and those predicted from a 3‐D model.…”

Section: Predicting Ground Electric Fields Through the Magnetotellurimentioning

confidence: 99%

“…There is growing recognition that the electrical conductivity of the crust and mantle varies strongly in all three spatial dimensions [ Kelbert et al ., ; Meqbel et al ., ; Schultz et al ., ; Evans et al ., ], and that 3‐D conductivity variations can lead to significant intensification of ground electric fields [ Thomson et al ., ; Bedrosian and Love , ; Love et al , ]. Solutions to calculating ground electric fields in the time domain that are related to GMDs for the coupled ionospheric‐Earth 3‐D induction problem often employ finite difference time domain solutions in massively parallel computing environments [e.g., Simpson , ].…”

Section: Introductionmentioning

confidence: 99%

Rapid prediction of electric fields associated with geomagnetically induced currents in the presence of three‐dimensional ground structure: Projection of remote magnetic observatory data through magnetotelluric impedance tensors

Bonner

Schultz

2017

Space Weather

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Ground level electric fields arising from geomagnetic disturbances (GMDs) are used by the electric power industry to calculate geomagnetically induced currents (GICs) in the power grid. Current industry practice is limited to electric fields associated with 1‐D ground electrical conductivity structure, yet at any given depth in the crust and mantle lateral (3‐D) variations in conductivity can span at least 3 orders of magnitude, resulting in large deviations in electric fields relative to 1‐D models. Solving Maxwell's equations for electric fields associated with GMDs above a 3‐D Earth is computationally burdensome and currently impractical for industrial applications. A computationally light algorithm is proposed as an alternative. Real‐time data from magnetic observatories are projected through multivariate transfer functions to locations of previously occupied magnetotelluric (MT) stations. MT time series and impedance tensors, such as those publically available from the NSF EarthScope Program, are used to scale the projected magnetic observatory data into local electric field predictions that can then be interpolated onto points along power grid transmission lines to actively improve resilience through GIC modeling. Preliminary electric field predictions are tested against previously recorded time series, idealized transfer function cases, and existing industry methods to assess the validity of the algorithm for potential adoption by the power industry. Some limitations such as long‐period diurnal drift are addressed, and solutions are suggested to further improve the method before direct comparisons with actual GIC measurements are made.

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Geoelectric hazard maps for the continental United States

Cited by 42 publications

References 49 publications

Geoelectric Hazard Maps for the Pacific Northwest

Geoelectric Hazard Maps for the Pacific Northwest

Geoelectric hazard assessment: the differences of geoelectric responses during magnetic storms within common physiographic zones

Rapid prediction of electric fields associated with geomagnetically induced currents in the presence of three‐dimensional ground structure: Projection of remote magnetic observatory data through magnetotelluric impedance tensors

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